In this Oct. 29, 2013, photo Richard Gaitskell, study co-investigator from Brown University, explains an experiment being conducted deep in an abandoned gold mine in Lead, S.D., gold mine to search for elusive and mysterious dark matter. Gaitskell, in an announcement released Wednesday, said scientists at the Sanford Underground Research Facility found absolutely no evidence of dark matter in what is the most technologically advanced Earth-based search for the material that has mass but cannot be seen. They’ll keep looking for another year, but scientists were not optimistic about finding dark matter with the current setup and are already planning to build a more sensitive experiment on the site. (AP Photo/Chet Brokew)

LEAD, S.D. (AP) — Nearly a mile underground in an abandoned gold mine, one of the most important quests in physics has come up empty-handed in the search for the elusive substance known as dark matter, scientists announced Wednesday.

The most advanced Earth-based search for the mysterious material that has mass but cannot be seen turned up "absolutely no signal" of dark matter, said Richard Gaitskell of Brown University, a scientist working on the Large Underground Xenon experiment, or LUX. A detector attached to the International Space Station has so far also failed to find any dark matter, either.

Physicists released their initial findings Wednesday after the experiment's first few months of operation at the Sanford Underground Research Facility, which was built in the former Homestake gold mine in South Dakota's Black Hills.

With 4,580 feet of earth helping screen out background radiation, scientists tried to trap dark matter, which they hoped would be revealed in the form of weakly interacting massive particles, nicknamed WIMPS. The search, using the most sensitive equipment in the world, tried looking for the light fingerprint of a WIMP bouncing off an atomic nucleus of xenon cooled to minus 150 degrees.

But nothing was found, The team plans to keep looking for another year, but members are not optimistic about finding dark matter with the current setup. They are already planning to build a more sensitive experiment on the site, using a bigger tank of xenon.

"The short story is that we didn't see dark matter interacting, but we had the most sensitive search for dark matter ever performed in the world," said Daniel McKinsey, a physicist at Yale University.

The lab, in a bright, clean space at the end of an old mining tunnel filled with pipes and electric cables, is reached by a 10-minute ride in an elevator that once carried miners. Gaitskell and McKinsey said the experiment has far less radiation interference from cosmic rays than any other dark-matter lab.

Essentially, scientists are searching for something they are fairly sure exists and is crucial to the entire universe. But they do not know what it looks like or where to find it. And they are not sure if it's a bunch of light particles that weakly interact or if it is more like a black hole.

"It's ghost-like matter," McKinsey said.

Researchers "are really searching in the dark in a way," said Harvard University physicist Avi Loeb, who is not part of the LUX team. "We have no clue. We don't know what this matter is."

Even more so than the recently discovered Higgs boson, dark matter is central to the universe.

About one-quarter of the cosmos is comprised of dark matter — five times that of the ordinary matter that makes up everything we see. Dark matter is often defined by what it isn't: something that can be seen and something that is energy.

Scientists are pretty sure dark matter exists, but they are not certain what it is made of or how it interacts with ordinary matter. It is considered vital to all the scientific theories explaining how the universe is expanding and how galaxies move and interact.

"We know there's stuff out there that is something else and that makes these searches hugely important because we know we are missing most of the universe," said Neal Weiner, director of the Center for Cosmology and Particle Physics at New York University, who was not part of the search.

Gaitskell and McKinsey said they looked for three "candidate WIMP events" that other teams' experiments hinted at finding. And LUX came up completely empty, indicating that those other experiments must not have found anything.

The lack of success could just mean the equipment isn't sensitive enough, so bigger, more sensitive and expensive instruments will be needed, Gaitskell and McKinsey said.

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